Tier-optimized write scheme

ABSTRACT

A request to write data corresponding to at least a first portion of a file is received. It is determined whether to perform the request either as an in-place write or as an out-of-place write. Performing the in-place write comprises performing a write to a low latency storage device, and performing the out-of-place write comprises performing a write to a higher latency storage device. The request is performed as either the in-place write or the out-of-place write based on the determination. Performing the request as the in-place write includes writing the data to a first location on a storage tier storing the first portion of the file, and performing the request as the out-of-place write includes writing the data to a second location on one of a plurality of storage tiers of a computing node, other than the first location.

CROSS REFERENCE TO OTHER APPLICATIONS

This application is a continuation of co-pending U.S. patent applicationSer. No. 15/628,445 entitled TIER-OPTIMIZED WRITE SCHEME filed Jun. 20,2017, which is a continuation of U.S. patent application Ser. No.14/684,536, now U.S. Pat. No. 9,696,913, entitled TIER-OPTIMIZED WRITESCHEME filed Apr. 13, 2015, all of which are incorporated herein byreference for all purposes.

BACKGROUND Field

Embodiments presented herein generally relate to optimizing a tieredstorage system. More specifically, embodiments presented herein providea tiered storage system optimized to perform write operations.

Description of the Related Art

A distributed computing system includes multiple computer systems whichinteract with one another to achieve a common goal. Computer systems inthe distributed computing system share different resources, such asdata, storage, processing power, and the like.

One storage configuration for a distributed computing system includeshard disk drives (HDDs) that store data supported by a cache stored in asolid state drive (SSD). When the system performs write I/O operationsfile, the system can write the data either in-place or out-of-place.Generally, in-place write operations are more efficiently performed inSSDs than HDDs due to lower seek time needed to access data. However,SSDs typically have a lower capacity than HDDs. Therefore, the SSDs areoften used to provide a cache for the HDDs, which ultimately store thedata.

Sequential writes are more efficient than writes performed to randomlocations. To address this, the system frequently improves performanceby performing writes “out-of-place.” To do so, a write operation isfirst performed to a new location on disk instead of overwriting data ina currently existing location. The new location may then be referenced.As a result, the old location contains unreferenced data. The systemmust then perform garbage collection at the old location so that otherdata may be written to that location.

SUMMARY

Embodiments presented herein provide a method for storing data in aplurality of storage tiers on a computing node. The method generallyincludes receiving a request to write data corresponding to at least afirst portion of a file. The method also includes determining whether toperform the request either as an in-place write or as an out-of-placewrite. Upon determining to perform the request as the in-place write,the data is written to a first location on a storage tier whichcurrently stores the first portion of the file. Upon determining toperform the request as the out-of-place write, the data is written to asecond location on one of the storage tiers, other than the firstlocation.

Other embodiments include, without limitation, a computer-readablemedium that includes instructions that enable a processing unit toimplement one or more aspects of the disclosed methods as well as asystem having a processor, memory, and application programs configuredto implement one or more aspects of the disclosed methods.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an example computing environment, according to oneembodiment.

FIG. 2 illustrates an example secondary storage server, according to oneembodiment.

FIG. 3 illustrates an example binary large object (blob) structure,according to one embodiment.

FIG. 4 illustrates a tier-based storage layout in the secondary storageserver described in FIG. 2, according to one embodiment.

FIG. 5 illustrates a method for performing a write operation, accordingto one embodiment.

FIG. 6 illustrates a method for determining whether to write a filechunk out-of-place or in-place, according to one embodiment.

FIG. 7 illustrates a secondary storage system, according to oneembodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments presented herein provide a tiered storage system for adistributed computing system cluster. More specifically, embodimentsdescribe techniques for optimizing write operations by using a tieredstorage system. In one embodiment, each system in a distributed clusterincludes both solid state drives (SSD) and hard disk drives (HDDs).Further, the SSD acts as an upper tier for storing hot data, i.e., datacurrently being accessed by clients of the tiered storage system.Because HDDs generally provide much larger storage capacity than SSDs(at a much lower cost per unit of space), HDDs act as a lower tier forstoring cold data, i.e., data that are not currently being accessed byclients of the tiered storage system.

In one embodiment, a node in the cluster may receive a request to writedata to a file. If the portion of the file specified in the request doesnot contain any prior data, then chunks corresponding to that portion donot exist. In such a case, the node writes the data out-of-place tonewly-created chunks. In a storage node, chunks can be stored on eitherthe SSD or the HDD. The new chunks may be created on either the SSD orthe HDD based on an incoming I/O access pattern. If the pattern israndom, then the node creates the new chunks on SSD. On the other hand,if the pattern is sequential, then the node creates the new chunks onHDD. Further, regardless of whether the chunks are written to the SSD orHDD, the node writes the chunks sequentially.

Otherwise, if chunks corresponding to the portion of the file in therequest already exist, the node writes the data to a chunk containingthe portion of the file to be written to. In one embodiment, when a nodein the cluster receives a request to write data to a file, the tieredstorage system writes the data to a portion of the file currently beingwritten to in-place on the SSD (i.e., updates the data in correspondingchunks) provided that no overriding conditions exist. Examples of suchoverriding conditions are whether the corresponding chunks are immutable(e.g., the chunks are deduplicated), whether the chunks are part of acompressed group, and whether the corresponding chunks are currentlystored on HDD and the incoming access pattern is random. If any of thoseconditions are satisfied, then the node writes the data out-of-place toSSD or HDD (based on the underlying access pattern).

Embodiments presented herein may be adapted to a variety of storagesystems, e.g., primary storage systems, secondary storage systems, etc.For example, consider a secondary storage system used to backup datastored in a primary storage system. The secondary storage system may doso by creating snapshots of the primary storage systems at specifiedintervals. The secondary storage system may capture snapshots ofrelatively large storage objects, such as virtual machine disk objects,databases, and the like. In addition, clients may access copies of thesnapshot for a variety of purposes (e.g., test and development). Thus,the secondary storage system may need to perform multiple random I/Ooperations on large amounts of data at any given time. Based on theservices provided by the secondary storage system, data maintained bythe system may, at any time, go from hot to cold, and vice versa.

In one embodiment, nodes of the secondary storage system may providemultiple storage tiers for storing backups of the primary storagesystem. For example, an upper tier backed by a SSD may handle randomwrite operations, while a lower tier backed by HDD(s) may provide verylarge storage capacity. Generally, when a node receives a request towrite to a portion of the file in the SSD, the node writes directlyin-place (i.e., overwrite the existing chunks) in the SSD. The SSD canperform in-place write operations more efficiently than an HDD.

Further, the node may also decide whether to write data in the uppertier or the lower tier based on properties of the corresponding datachunk and the write operation. For example, the node first determineswhether a portion of the file corresponding to a write request isassociated with existing chunks. If not, the node creates new chunkssequentially and writes the data to the new chunks. The node may createthe new chunks in the SSD or HDD based on an incoming access pattern.For instance, if the incoming pattern is random, then the chunks arecreated on SSD. Otherwise, if the incoming pattern is sequential, thenthe chunks are created on HDD. If the portion of the file is associatedwith existing chunks, the node writes in-place to SSD if no overridingconditions exist. For example, the node may write out-of-place if thechunks correspond to a compressed group of chunks. Doing so results inmore efficient performance, i.e., rather than decompress the group,update the data chunk on the HDD, and re-compress the group, the nodeinstead writes the chunk on the SSD. Further, the node may also writeout-of-place if the chunks are deduplicated. In addition, the node maywrite-out-of-place if the incoming access pattern is random and thechunks are located on the HDD.

The tiered storage system disclosed herein determines whether to write afile chunk to in-place or out-of-place within the secondary storagesystem based on various factors such as whether the data is currentlyaccessed and the location and properties of a targeted file chunk (ifthe chunk currently exists). Advantageously, doing so allows the tieredstorage to optimally perform in-place or out-of-place write operationsas well as send as many write operations to the SSD relative to the HDD.Doing so reduces overhead incurred in performing random I/O operationsto HDD by fully utilizing faster writes to the SSD. Further, whenwriting data to the HDD, the node can group chunks of data to writetogether in a given area of the HDD, allowing for sequentialperformance.

Note, embodiments are described using a distributed secondary storagesystem as a reference example of a computing system which can takeadvantage of a tiered storage system described herein. However, one ofordinary skill in the art will recognize that the tiered storage systemmay be adapted to efficiently store data for a variety of computingsystems.

FIG. 1 illustrates an example computing environment 100, according toone embodiment. As shown, the computing environment includes a primarystorage server 105 and a distributed cluster 122. The distributedcluster 122 includes multiple computing servers 110 configured to hostand manage a service (e.g., secondary storage services). The primarystorage server 105 and secondary storage servers 110 are each connectedvia a network 120. The primary storage server 105 and secondary storageservers 110 may provide storage for a large data center.

In this example embodiment, secondary storage servers 110 provide backupstorage and services to the primary storage server 105. The backupservices may be workloads for copying data to tape disks, moving data toa cloud provider, and performing test and development tasks using aclone of the backup data. As shown, each secondary storage server 110(or “node”) includes bridge components 112 and data gathering components114. The bridge components 112 may allow external clients to access eachnode. The data gathering components 114 retrieve data from primarystorage server 105 (e.g., by communicating with the primary storageserver 105 using a backup protocol). Further, each node includes one ormore hard disk drives (HDDs) 116 and solid-state drives (SSDs) 118 forstoring data from primary storage server 105. The SSDs 118 increase theperformance running secondary storage transactions, such asnon-sequential write transactions.

Further, the SSDs 118 and HDDs 116, together, provided a tiered storagesystem which can efficiently perform a large volume of write operations.The SSDs 118 form an upper tier that stores “hot” data (i.e., filechunks that are frequently accessed by the secondary storage server110). The HDDs 116 form a lower tier that storages “cold” data (i.e.,file chunks that are not currently accessed by the secondary storageserver 110).

FIG. 2 further illustrates an example secondary storage server 110,according to one embodiment. As shown, the secondary storage server 110includes bridge components 112, data gathering components 114, a nodeidentifier 205, and a file system 210.

As stated, the data gathering components 114 may communicate withprimary storage servers in the computing environment 100. To do so, thedata gathering components 114 may include adapters specific tocommunicating with backup protocols hosted on primary storage servers.Illustratively, the data gathering components 114 may retrieve data fromprimary storage servers 201 and 202, where each primary storage server201 and 202 execute backup protocols such as recovery manager (RMAN) 203and vStorage APIs for Data Protection (VADP).

The secondary storage server 110 includes a file system 210. The filesystem 210 collaborates with the file systems of other secondary storageservers in the cluster to form a distributed system used to store backupdata from the primary storage service 201. For example, assume thebridge components 112 receive a virtual machine disk (VMDK) file fromthe backup data gathering components 114. In such a case, the bridgecomponents 112 writes the VMDK file to disk storage 160. In addition,file system metadata (e.g., inodes) are stored in SSD 118. However as aVMDK file can be quite large (e.g., terabytes), bridge components 112may store the VMDK file as a blob (binary large object). The blob may befurther divided into a set of chunks (e.g., 8 KB each), which are storedin numerous chunk files. Backup data below a given size threshold (e.g.,files less than 256K bytes) could be stored in the SSD 118 directlyalong with the file system metadata.

Once stored, the bridge components 112 may expose file system 210 tovarious clients through file system protocols, such as NFS, SMB, andiSCSI. Further, the bridge components 112 may respond to operationrequests received from the clients.

Data in the secondary storage server 110 may be stored in distributed B+trees or blob structures. In one embodiment, data smaller than 256 KBresides in distributed B+ trees, and data larger than 256 KB is storedin blob structures. The secondary storage server 200 may maintain a blobstore 214 that contains the blob structures. Each blob may be dividedinto regions of a particular size, such as 128 KB. These regions, or“bricks,” may further contain chunks of data that reference logicalfiles in the SSD 118 and the HDDs 116.

The scribe process 214 maintains the data residing in distributed B+trees. Further, the scribe process 214 also maintains information aboutthe chunks of data in the blob store 210 in key-value stores (e.g., treestructures). One example key-value store may map blob structures tobrick sections. Another store may map bricks to chunks. Yet anotherstore may map chunks to logical files storage drives of the secondarystorage server 110.

As stated, the SSDs 118 and HDDs 116 provide tiered storage system,where the SSDs 118 form an upper first tier that stores hot data. Assuch, the node performs write operations to the SSDs 118. In contrast,the HDDs 116 form a lower tier that generally stores cold data due tolarger capacity of HDDs relative to SSDs. The scribe process 214 maystore metadata describing the location of the chunks written to SSD andHDD.

FIG. 3 illustrates a blob 300, according to one embodiment. As stated,file data may be contained within the blob 300. The blob 300 is dividedinto regions of equal size, or bricks 305 (represented by the numberedregions 0-6). The bricks 305 each contain chunks 310. Each chunk 310 mayreference a file stored by the secondary storage server 110. The bricks305 and chunks 310 may contain identifiers used by the scribe process214 in key-value stores that map to the stored files.

In one embodiment, a chunk 310 can be either deduplicated ornon-deduplicated. In the secondary storage system, incoming write datamay be similar or identical to data that has previously been written todisk. In such a case, the chunk 310 representing that data is adeduplicated chunk. Thus, when the node identifies identical data is tobe written, the node can create identifier referencing the deduplicatedchunk. In addition, because other chunks may reference the deduplicatedchunk, the node generally does not overwrite a deduplicated chunk.

Further, in one embodiment, a chunk 310 can be a part of a compressedgroup of chunks. That is, nodes in the secondary storage system canpreserve storage space by compressing data chunks 310. In oneembodiment, when updating data of a chunk 310 that is part of acompressed group, the node typically performs an out-of-place writeoperation to create a new chunk, rather than update the chunk 310in-place. The node updates file metadata to reference the new chunk.Doing so avoids performance overhead in uncompressing the chunk group,updating the chunk, and re-compressing the chunk group.

FIG. 4 illustrates a tier-based storage layout in the secondary storageserver 110, according to one embodiment. As stated, the SSDs 118 canprovide an upper tier storing hot data, i.e., data that is recentlyaccessed in the secondary storage system. The HDDs 116 generally havelarger capacity than the SSDs 118 and provide a lower tier that storeslarge amounts of backup data. As stated, the secondary storage server110 optimizes write operations such that hot data is written to chunksstored in the SSDs 118. When a given chunk has not been accessed after aspecified period of time, a background process may flush the chunk tothe HDDs 116.

Illustratively, FIG. 4 shows a file 405 stored in the SSD 118 in tier 1401 and a file 410 stored in the HDD 116 in tier 2 402. When bridgecomponents 112 receives a write operation for a portion of a given file,the bridge process first identifies the location of the chunk (if theportion of the file contains prior data), i.e., whether the chunk isstored in tier 1 401 or tier 2 402. In one embodiment, the bridgeprocess identifies the location in a key-value store maintained in thescribe process 214.

If the relevant chunk is stored in tier 1 401 (e.g., such as file 405),then the bridge process typically writes in-place to the identifiedlocation in SSD 118. However, in some cases, then the bridge processwrites out-of-place, i.e., creates new chunks on SSD or HDD (based on anincoming I/O access pattern) and writes to those chunks. For example,the bridge process does not write to deduplicated chunks in-placebecause such chunks may be based on a SHA-1 fingerprint and alsoreferenced by other files. Therefore, rather than attempt to overwritethe deduplicated chunk, the bridge process writes a new chunkout-of-place to a new location on storage instead. Another example wherethe bridge process writes out-of-place is where the chunk is stored asone of many compressed chunks. That is, the writing in place to a chunkthat is part of a compressed group incurs significant performanceoverhead, as the bridge process would need to uncompress the group,update the chunk, and then re-compress the group. When creating a newchunk, the bridge process determines an incoming I/O access pattern. Ifthe access pattern is random, then the bridge process places the chunkssequentially in the SSD. Otherwise, if the access pattern is sequential,then the bridge process places the chunks in the HDD. Doing so allowsfor subsequent sequential reads on the HDD.

If an overriding condition exists, the bridge process writes the filechunk out-of-place. Illustratively, file chunks A and B are written indifferent locations on the SSD 118. On the other hand, if the file isstored in tier 2 402 (e.g., such as file 410) and if the access patternis sequential, the bridge process writes the chunk out-of-place to theHDDs 116.

In one embodiment, a background process periodically scans the SSD 118to identify chunks that have not been accessed in the SSD for aspecified amount of time. The background process transfers such chunksto the HDD 116. Doing so ensures the SSD 118 should have capacity tostore hot data over time. The background process also updates thekey-value store maintained by the scribe process 214 to reflect thechange in location.

FIG. 5 illustrates a method 500 for performing a write I/O operation,according to one embodiment. Method 500 begins at step 505, where thebridge process receives an incoming request to perform a write operationto a file.

At step 510, the bridge process accesses metadata associated with thefile. Such metadata may be located in the key-value mapping tablesmaintained by the scribe process 214. The metadata can describe variousproperties of a chunk associated with a portion of a file to be written,such as the location (e.g., whether the chunk is stored on the SSD orHDD), whether the chunk is deduplicated, part of a compressed group,etc. In one embodiment, the scribe process may determine the location ofthe metadata in the key-value stores. If the portion of the file doesnot contain any prior data, then a corresponding chunk does not existfor the data. In such a case, the bridge process writes the chunkout-of-place to the appropriate tier (based on an incoming accesspattern).

If the data corresponds to an existing chunk, then at step 515, thebridge process determines whether to write the chunk to the upper tieror the lower tier of storage based on the location and properties of thechunk. For example, the bridge process may make such determination basedon the current location of the chunk, whether the underlying writeoperation is random or sequential, whether the chunk is deduplicated,and whether the file chunk is part of a compressed chunk group.

At step 520, the bridge process determines whether to write either tothe upper tier or lower tier. If the bridge process determines to writeto the upper tier, the bridge process writes to a location on the SSD(step 525). Such determination is based on whether an incoming accesspattern of the write operation is random or sequential, as described inmore detail below. Further, at step 530, the bridge process updates thefile chunk metadata to reflect the update. If the bridge processdetermines to write to the lower tier, the bridge process writes to alocation on the HDD (at step 535). At step 540, the bridge process thenupdates the file chunk metadata to reference the location on the HDD.

FIG. 6 illustrates a method 600 for determining whether to write a chunkto disk in-place or out-of-place, according to one embodiment. Asstated, when the bridge process receives an incoming write operation fora portion of a file, the bridge process obtains file metadata from thekey-value tables maintained by the scribe process 214. The metadatadescribes the chunk used to store the file (or portion of the file) inthe secondary storage system, if the chunk exists (i.e., the portion ofthe file contains prior data). At step 605, the bridge process accessesthe file metadata. The bridge process may identify the location from themetadata.

At step 610, the bridge process determines whether prior data exists forthe file portion. If prior data does not exist, then a correspondingchunk for the data to be written also does not exist. Consequently, atstep 615, the bridge process writes the chunk out-of-place to theappropriate tier based on the access pattern. That is, if the accesspattern corresponds to a random pattern, then the bridge process writesthe chunk to SSD. And if sequential, then the bridge process writes thechunk to HDD.

Otherwise, if prior data does exist (i.e., corresponding chunks alsoexist), then the bridge process determines whether any existingconditions exist that would cause the bridge process to write thecorresponding chunk out-of-place. As stated, examples of overridingconditions include an existing chunk being part of a compressed chunkgroup or being deduplicated. If a given chunk is written out-of-place,the bridge process also updates the file metadata to point to the chunkat the new location.

For instance, at step 620, the bridge process determines whether thechunk is a deduplicated chunk. In such a case, rather than overwritingthe deduplicated chunk, the bridge process should create a new chunk viaan out-of-place write operation (at step 615). Therefore, if the chunkis a deduplicated chunk, then the bridge process determines to write thechunk out-of-place. If not, then at step 625, the bridge processdetermines whether the chunk is part of a compressed chunk group. If so,then the bridge process opts to write the chunk out-of-place (at step615).

If not, then at step 630, the bridge process determines whether theunderlying access pattern is random or sequential. To do so, the bridgeprocess may call a pattern detection process executing within the node.As stated, the pattern detection process tracks streams of incoming I/Ooperations and identifies whether each pattern is random or sequential.If sequential, then at step 640, the bridge process overwrites theexisting chunk in-place. However, if random, then at step 645, thebridge process determines whether chunk is stored on HDD or SSD. If thechunk is stored on the SSD, then the bridge process overwrites theexisting chunk in-place (at step 640). Otherwise, if the chunk is storedon the HDD, then the bridge process writes the chunk to a new locationout-of-place (at step 615). The bridge process updates the file metadatato point the chunk at the new location.

FIG. 7 illustrates an example secondary storage server 700, according toone embodiment. As shown, computing system 700 includes, withoutlimitation, a central processing unit (CPU) 705, a network interface715, a memory 720, and storage 730, each connected to a bus 717. Server700 may also include an I/O device interface 710 connecting I/O devices712 (e.g., keyboard, display and mouse devices) to the server 700.Further, in context of this disclosure, the computing elements shown inthe secondary storage server 700 may correspond to a physical computingsystem (e.g., a system in a data center).

CPU 705 retrieves and executes programming instructions stored in memory720 as well as stores and retrieves application data residing in thestorage 730. The bus 717 is used to transmit programming instructionsand application data between CPU 705, I/O devices interface 710, storage730, network interface 715, and memory 720. Note, CPU 705 is included tobe representative of a single CPU, multiple CPUs, a single CPU havingmultiple processing cores, and the like. Memory 720 is generallyincluded to be representative of a random access memory. Storage 730 maybe a disk drive storage device. Although shown as a single unit, storage730 may be a combination of fixed and/or removable storage devices, suchas fixed disc drives, removable memory cards, or optical storage,network attached storage (NAS), or a storage area-network (SAN).

Illustratively, memory 720 includes bridge components 724, a file system725, and data gathering components 726. The file system 725 collaborateswith the file systems of other secondary storage systems to store backupdata from a primary storage system. The bridge components 724 may exposethe file system 725 to various clients through file system protocols.

In addition, the bridge components 724 receive incoming random I/Ooperation requests (e.g., from clients). In turn, the bridge components724 perform the requested operations. Further, the data gatheringcomponents 726 allow the secondary storage server 700 to communicatewith primary storage servers and retrieve data from the primary storageservers.

The storage 730 is divided into an SSD 734 and HDD 735. Each drivestores files 735 based on whether the data is recently accessed. Morespecifically, the SSD 734 serves as a upper tier that stores “hot” data(e.g., files 735 ₁), and the HDD 735 serves as a lower tier that stores“cold” data (e.g., files 735 ₂). A scribe process may maintain key-valuestores that map metadata corresponding to the files 735 to a givenlocation on one of the storage drives (i.e., SSD 734 and HDD 735).

A bridge process receives requests to perform write operations to afile. The bridge process determines whether to write to the file on theupper tier or the lower tier, e.g., by identifying the location of achunk in file metadata and making the determination based on thelocation. If the chunk is stored on the HDD, then the bridge processwrites to the lower tier. Otherwise, if the chunk is stored on the SSD,then the bridge process writes to the upper tier unless overridingconditions exist. Examples of overriding conditions include whether thechunk is deduplicated, whether the chunk is part of a compressed group,and whether the pattern of I/O operations is random or sequential.

Aspects of the present disclosure may be embodied as a system, method orcomputer program product. Accordingly, aspects of the present disclosuremay take the form of an entirely hardware embodiment, an entirelysoftware embodiment (including firmware, resident software, micro-code,etc.) or an embodiment combining software and hardware aspects that mayall generally be referred to herein as a “circuit,” “module” or“system.” Furthermore, aspects of the present disclosure may take theform of a computer program product embodied in one or more computerreadable medium(s) having computer readable program code embodiedthereon.

Any combination of one or more computer readable medium(s) may beutilized. The computer readable medium may be a computer readable signalmedium or a computer readable storage medium. A computer readablestorage medium may be, for example, but not limited to, an electronic,magnetic, optical, electromagnetic, infrared, or semiconductor system,apparatus, or device, or any suitable combination of the foregoing. Morespecific examples a computer readable storage medium include: anelectrical connection having one or more wires, a portable computerdiskette, a hard disk, a random access memory (RAM), a read-only memory(ROM), an erasable programmable read-only memory (EPROM or Flashmemory), an optical fiber, a portable compact disc read-only memory(CD-ROM), an optical storage device, a magnetic storage device, or anysuitable combination of the foregoing. In the current context, acomputer readable storage medium may be any tangible medium that cancontain, or store a program for use by or in connection with aninstruction execution system, apparatus or device.

The flowchart and block diagrams in the Figures illustrate thearchitecture, functionality and operation of possible implementations ofsystems, methods and computer program products according to variousembodiments of the present disclosure. In this regard, each block in theflowchart or block diagrams may represent a module, segment or portionof code, which comprises one or more executable instructions forimplementing the specified logical function(s). In some alternativeimplementations the functions noted in the block may occur out of theorder noted in the figures. For example, two blocks shown in successionmay, in fact, be executed substantially concurrently, or the blocks maysometimes be executed in the reverse order, depending upon thefunctionality involved. Each block of the block diagrams and/orflowchart illustrations, and combinations of blocks in the blockdiagrams and/or flowchart illustrations can be implemented byspecial-purpose hardware-based systems that perform the specifiedfunctions or acts, or combinations of special purpose hardware andcomputer instructions.

The foregoing description, for purpose of explanation, has beendescribed with reference to specific embodiments. However, theillustrative discussions above are not intended to be exhaustive or tolimit the disclosure to the precise forms disclosed. Many modificationsand variations are possible in view of the above teachings. Theembodiments were chosen and described in order to best explain theprinciples of the disclosure and its practical applications, to therebyenable others skilled in the art to best utilize the disclosure andvarious embodiments with various modifications as may be suited to theparticular use contemplated.

While the foregoing is directed to embodiments of the presentdisclosure, other and further embodiments of the disclosure may bedevised without departing from the basic scope thereof, and the scopethereof is determined by the claims that follow.

What is claimed is:
 1. A method for storing data, the method comprising:receiving a request to write data corresponding to at least a firstportion of a file; determining whether to perform the request either asan in-place write or as an out-of-place write, wherein performing thein-place write comprises performing a write to a low latency storagedevice, and performing the out-of-place write comprises performing awrite to a higher latency storage device; and performing the request aseither the in-place write or the out-of-place write based on thedetermination, wherein performing the request as the in-place writeincludes writing the data to a first location on a storage tier storingthe first portion of the file, and performing the request as theout-of-place write includes writing the data to a second location on oneof a plurality of storage tiers of a computing node, other than thefirst location.
 2. The method of claim 1, wherein it is determined toperform the request as the out-of-place write including by determiningthat the first portion of the file corresponds to a deduplicatedportion.
 3. The method of claim 1, wherein it is determined to performthe request as the out-of-place write including by determining that thefirst portion of the file corresponds to a compressed group of portionsfrom one or more files.
 4. The method of claim 1, further comprising:recording a pattern of input or output operations to one or moreportions of the file.
 5. The method of claim 4, further comprising:determining, based on the recorded pattern of the input or outputoperations, whether to perform the request as either the in-place writeor as the out-of-place write.
 6. The method of claim 5, whereindetermining, based on the recorded pattern of the input/outputoperations, whether to perform the request as the out-of-place writecomprises: determining that the recorded pattern of input or outputoperations corresponds to a sequential pattern of input or outputoperations.
 7. The method of claim 5, further comprising: determining,based on the recorded pattern of the input or output operations, whetherto write the data to the first location on the storage tier whichcurrently stores the first portion of the file or to the second locationon one of the storage tiers, other than the first location.
 8. Themethod of claim 1, wherein the computing node is a node of a secondarystorage system.
 9. A system, comprising: a processor; and a memorycoupled with the processor, wherein the memory is configured to providethe processor with instructions which when executed cause the processorto: receive a request to write data corresponding to at least a firstportion of a file; determine whether to perform the request either as anin-place write or as an out-of-place write, wherein performing thein-place write comprises performing a write to a low latency storagedevice, and performing the out-of-place write comprises performing awrite to a higher latency storage device; and perform the request aseither the in-place write or the out-of-place write based on thedetermination, wherein performing the request as the in-place writeincludes writing the data to a first location on a storage tier storingthe first portion of the file, and performing the request as theout-of-place write includes writing the data to a second location on oneof a plurality of storage tiers of a computing node, other than thefirst location.
 10. The system of system 9, wherein it is determined toperform the request as the out-of-place write including by determiningthat the first portion of the file corresponds to a deduplicatedportion.
 11. The system of system 9, wherein it is determined to performthe request as the out-of-place write including by determining that thefirst portion of the file corresponds to a compressed group of portionsfrom one or more files.
 12. The system of system 9, wherein the memoryis further configured to provide the processor with instructions whichwhen executed cause the processor to: record a pattern of input oroutput operations to one or more portions of the file.
 13. The system ofsystem 12, wherein the memory is further configured to provide theprocessor with instructions which when executed cause the processor to:determine, based on the recorded pattern of the input or outputoperations, whether to perform the request as either the in-place writeor as the out-of-place write.
 14. The system of system 13, whereindetermining, based on the recorded pattern of the input/outputoperations, whether to perform the request as the out-of-place writecomprises: determining that the recorded pattern of input or outputoperations corresponds to a sequential pattern of input or outputoperations.
 15. The system of system 13, wherein the memory is furtherconfigured to provide the processor with instructions which whenexecuted cause the processor to: determine, based on the recordedpattern of the input or output operations, whether to write the data tothe first location on the storage tier which currently stores the firstportion of the file or to the second location on one of the storagetiers, other than the first location.
 16. The system of system 9,wherein the computing node is a node of a secondary storage system. 17.A computer program product for storing data, the computer programproduct being embodied in a non-transitory computer readable storagemedium and comprising computer instructions for: receiving a request towrite data corresponding to at least a first portion of a file;determining whether to perform the request either as an in-place writeor as an out-of-place write, wherein performing, the in-place writecomprises performing a write to a low latency storage device andperforming the out-of-place write comprises performing a write to ahigher latency storage device; and performing the request as either thein-place write or the out-of-place write based on the determination,wherein performing the request as the in-place write includes writingthe data to a first location on a storage tier storing the first portionof the file, and performing the request as the out-of-place writeincludes writing the data to a second location on one of a plurality ofstorage tiers of a computing node, other than the first location. 18.The computer program product of claim 17, wherein it is determined toperform the request as the out-of-place write including by determiningthat the first portion of the file corresponds to a deduplicatedportion.
 19. The computer program product of claim 17, wherein it isdetermined to perform the request as the out-of-place write including bydetermining that the first portion of the file corresponds to acompressed group of portions from one or more files.
 20. The computerprogram product of claim 17, further comprising computer instructionsfor recording a pattern of input or output operations to one or moreportions of the file.